#include #include #include void RgbCctPacketFormatter::modeSpeedDown() { command(RGB_CCT_ON, RGB_CCT_MODE_SPEED_DOWN); } void RgbCctPacketFormatter::modeSpeedUp() { command(RGB_CCT_ON, RGB_CCT_MODE_SPEED_UP); } void RgbCctPacketFormatter::updateMode(uint8_t mode) { lastMode = mode; command(RGB_CCT_MODE, mode); } void RgbCctPacketFormatter::nextMode() { updateMode((lastMode+1)%RGB_CCT_NUM_MODES); } void RgbCctPacketFormatter::previousMode() { updateMode((lastMode-1)%RGB_CCT_NUM_MODES); } void RgbCctPacketFormatter::updateBrightness(uint8_t brightness) { command(RGB_CCT_BRIGHTNESS, RGB_CCT_BRIGHTNESS_OFFSET + brightness); } void RgbCctPacketFormatter::updateHue(uint16_t value) { uint8_t remapped = Units::rescale(value, 255, 360); updateColorRaw(remapped); } void RgbCctPacketFormatter::updateColorRaw(uint8_t value) { command(RGB_CCT_COLOR, RGB_CCT_COLOR_OFFSET + value); } void RgbCctPacketFormatter::updateTemperature(uint8_t value) { // Packet scale is [0x94, 0x92, .. 0, .., 0xCE, 0xCC]. Increments of 2. // From coolest to warmest. // To convert from [0, 100] scale: // * Multiply by 2 // * Reverse direction (increasing values should be cool -> warm) // * Start scale at 0xCC value = ((100 - value) * 2) + RGB_CCT_KELVIN_REMOTE_END; command(RGB_CCT_KELVIN, value); } void RgbCctPacketFormatter::updateSaturation(uint8_t value) { uint8_t remapped = value + RGB_CCT_SATURATION_OFFSET; command(RGB_CCT_SATURATION, remapped); } void RgbCctPacketFormatter::updateColorWhite() { updateTemperature(0); } void RgbCctPacketFormatter::enableNightMode() { uint8_t arg = groupCommandArg(OFF, groupId); command(RGB_CCT_ON | 0x80, arg); } BulbId RgbCctPacketFormatter::parsePacket(const uint8_t *packet, JsonObject& result, GroupStateStore* stateStore) { uint8_t packetCopy[V2_PACKET_LEN]; memcpy(packetCopy, packet, V2_PACKET_LEN); V2RFEncoding::decodeV2Packet(packetCopy); BulbId bulbId( (packetCopy[2] << 8) | packetCopy[3], packetCopy[7], REMOTE_TYPE_RGB_CCT ); uint8_t command = (packetCopy[V2_COMMAND_INDEX] & 0x7F); uint8_t arg = packetCopy[V2_ARGUMENT_INDEX]; if (command == RGB_CCT_ON) { if (arg == RGB_CCT_MODE_SPEED_DOWN) { result["command"] = "mode_speed_down"; } else if (arg == RGB_CCT_MODE_SPEED_UP) { result["command"] = "mode_speed_up"; } else if (arg < 5) { // Group is not reliably encoded in group byte. Extract from arg byte result["state"] = "ON"; bulbId.groupId = arg; } else { result["state"] = "OFF"; bulbId.groupId = arg-5; } } else if (command == RGB_CCT_COLOR) { uint8_t rescaledColor = (arg - RGB_CCT_COLOR_OFFSET) % 0x100; uint16_t hue = Units::rescale(rescaledColor, 360, 255.0); result["hue"] = hue; } else if (command == RGB_CCT_KELVIN) { // Packet range is [0x94, 0x92, ..., 0xCC]. Remote sends values outside this // range, so normalize. uint8_t temperature = arg; if (arg < 0xCC && arg >= 0xB0) { temperature = 0xCC; } else if (arg > 0x94 && arg <= 0xAF) { temperature = 0x94; } temperature = (temperature + (0x100 - RGB_CCT_KELVIN_REMOTE_END)) % 0x100; temperature /= 2; temperature = (100 - temperature); temperature = constrain(temperature, 0, 100); result["color_temp"] = Units::whiteValToMireds(temperature, 100); // brightness == saturation } else if (command == RGB_CCT_BRIGHTNESS && arg >= (RGB_CCT_BRIGHTNESS_OFFSET - 15)) { uint8_t level = constrain(arg - RGB_CCT_BRIGHTNESS_OFFSET, 0, 100); result["brightness"] = Units::rescale(level, 255, 100); } else if (command == RGB_CCT_SATURATION) { result["saturation"] = constrain(arg - RGB_CCT_SATURATION_OFFSET, 0, 100); } else if (command == RGB_CCT_MODE) { result["mode"] = arg; } else { result["button_id"] = command; result["argument"] = arg; } return bulbId; }